Project Abstract
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This project extended the Extreme Scale Discontinuous Galerkin Environment (EDGE) with a robust and accurate a posteriori finite volume sub-cell limiter. Sub-cell limiting is the new fundamental building block of the software to tackle demanding hyperbolic problems with strong non-linearities, especially in the context of emerging challenges in earthquake science. Further, over the duration of this project, we optimized and analyzed EDGE on commercial cloud solutions for high performance computing. A respective seismic simulation on 768 AWS c5.18xlarge instances, comprising 27,648 cores, sustained a performance of 1.09 FP32-PFLOPS [2]. This is, to the best of our knowledge, the first work of its kind at such a large scale. All conducted work of this project is publicly available through EDGE’s online resources. This includes all pre-processing scripts, the solver itself, and data, e.g., the layout of sub-grids or pre-computed operators.
The project covered four major steps, which are detailed throughout the project report. First, we derived sub-cell grids and operators in pre-processing through symbolic computations. Second, we included these pre-computed data structures in the main solver, running at high performance. Third, we enabled the a posteriori sub-cell limiting in the main solver, which requires the evaluation of admissibility criteria, projections of the DG-solution to the sub-cell-solution for inadmissible elements, time stepping of the sub-cell solution, and potential projections of the sub-cell solution to the DG-solution. Fourth, we tested the implemented procedure, when simulating seismic wave propagation. |
